Vacuum-integrated hardmask processes and apparatus

ABSTRACT

Vacuum-integrated photoresist-less methods and apparatuses for forming metal hardmasks can provide sub-30 nm patterning resolution. A metal-containing (e.g., metal salt or organometallic compound) film that is sensitive to a patterning agent is deposited on a semiconductor substrate. The metal-containing film is then patterned directly (i.e., without the use of a photoresist) by exposure to the patterning agent in a vacuum ambient to form the metal mask. For example, the metal-containing film is photosensitive and the patterning is conducted using sub-30 nm wavelength optical lithography, such as EUV lithography.

INCORPORATION BY REFERENCE

An Application Data Sheet is filed concurrently with this specificationas part of the present application. Each application that the presentapplication claims benefit of or priority to as identified in theconcurrently filed Application Data Sheet is incorporated by referenceherein in their entireties and for all purposes.

BACKGROUND

This disclosure relates generally to the field of semiconductorprocessing. In particular, the disclosure is directed tovacuum-integrated processes for forming metal hardmasks without the useof photoresist.

Patterning of thin films in semiconductor processing is often a criticalstep in the manufacture and fabrication of semiconductors. Patterninginvolves lithography. In conventional photolithography, such as 193 nmphotolithography, patterns are printed by emitting photons from a photonsource onto a mask and printing the pattern onto a photosensitivephotoresist, thereby causing a chemical reaction in the photoresistthat, after development, removes certain portions of the photoresist toform the pattern.

Advanced technology nodes (as defined by the International TechnologyRoadmap for Semiconductors) include nodes 22 nm, 16 nm, and beyond. Inthe 16 nm node, for example, the width of a typical via or line in aDamascene structure is typically no greater than about 30 nm. Scaling offeatures on advanced semiconductor integrated circuits (ICs) and otherdevices is driving lithography to improve resolution.

SUMMARY

Aspects of the present invention are directed to vacuum-integratedphotoresist-less methods and apparatuses for forming metal hardmasks.Such methods and apparatuses can provide sub-30 nm patterningresolution. Generally, a metal-containing (e.g., metal salt ororganometallic compound) film that is sensitive to patterning agent suchas photons, electrons, protons, ions or neutral species such that thefilm can be patterned by exposure to one of these species is depositedon a semiconductor substrate. The metal-containing film is thenpatterned directly (i.e., without the use of a photoresist) by exposureto the patterning agent in a vacuum ambient to form the metal mask. Forexample, the metal-containing film is photosensitive and the patterningis conducted using optical lithography, such as EUV lithography.

In one implementation, a EUV-sensitive metal-containing film isdeposited on a semiconductor substrate. The metal-containing film isthen patterned directly by EUV exposure in a vacuum ambient to form themetal hardmask. In this way, a vacuum-integrated metal hardmask processand related vacuum-integrated hardware that combine steps of filmformation (condensation/deposition) and optical lithography with theresult of greatly improved EUV lithography (EUVL) performance—e.g.reduced line edge roughness—is provided. By using a metal-containinghardmask and by directly patterning the metal-containing film using theEUV photon flux, the process entirely avoids the need for photoresist.

In another implementation, an apparatus for conducting photoresist-lessmetal hardmask formation can provide the vacuum integration to conductthe described processes. The apparatus includes a metal-containing filmdeposition module, a metal-containing film patterning module, and avacuum transfer module connecting the deposition module and thepatterning module.

These and other features and advantages of the invention will bedescribed in more detail below with reference to the associateddrawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A-1E illustrate a representative process flow for avacuum-integrated photoresist-less hardmask formation process.

FIG. 2 provides the emission spectrum of a EUV source which uses excitedSn droplets.

FIG. 3 depicts a semiconductor process cluster architecture with metaldeposition and patterning modules that interface with a vacuum transfermodule, suitable for implementation of the vacuum-integrated processesdescribed herein.

DETAILED DESCRIPTION

Reference will now be made in detail to specific embodiments of theinvention. Examples of the specific embodiments are illustrated in theaccompanying drawings. While the invention will be described inconjunction with these specific embodiments, it will be understood thatit is not intended to limit the invention to such specific embodiments.On the contrary, it is intended to cover alternatives, modifications,and equivalents as may be included within the spirit and scope of theinvention. In the following description, numerous specific details areset forth in order to provide a thorough understanding of the presentinvention. The present invention may be practiced without some or all ofthese specific details. In other instances, well known processoperations have not been described in detail so as to not unnecessarilyobscure the present invention.

Introduction

Extreme ultraviolet (EUV) lithography can extend lithographic technologybeyond its optical limits by moving to smaller imaging sourcewavelengths achievable with current photolithography methods to patternsmall critical dimension features. EUV light sources at approximately13.5 nm wavelength can be used for leading-edge lithography tools, alsoreferred to as scanners. The EUV radiation is strongly absorbed in awide range of solid and fluid materials including quartz and watervapor, and so operates in a vacuum.

EUV lithography typically makes use of an organic hardmask (e.g., anashable hardmark of PECVD amorphous hydrogenated carbon) that ispatterned using a conventional photoresist process. During photoresistexposure, EUV radiation is absorbed in the resist and in the substratebelow, producing highly energetic photoelectrons (about 100 eV) and inturn a cascade of low-energy secondary electrons (about 10 eV) thatdiffuse laterally by several nanometers. These electrons increase theextent of chemical reactions in the resist which increases its EUV dosesensitivity. However, a secondary electron pattern that is random innature is superimposed on the optical image. This unwanted secondaryelectron exposure results in loss of resolution, observable line edgeroughness (LER) and linewidth variation in the patterned resist. Thesedefects are replicated in the material to be patterned during subsequentpattern transfer etching.

Unlike an insulator such as photoresist, a metal is less susceptible tosecondary electron exposure effects since the secondary electrons canquickly lose energy and thermalize by scattering with conductionelectrons. Suitable metal elements for this process may include but arenot limited to: aluminum, silver, palladium, platinum, rhodium,ruthenium, iridium, cobalt, ruthenium, manganese, nickel, copper,hafnium, tantalum, tungsten, gallium, germanium, tin, antimony, or anycombination thereof.

However, electron scattering in the photoresist used to pattern ablanket metal film into a mask would still lead to unacceptable effectssuch as LER.

A vacuum-integrated metal hardmask process and related vacuum-integratedhardware that combines film formation (deposition/condensation) andoptical lithography with the result of greatly improved EUV lithography(EUVL) performance—e.g. reduced line edge roughness—is disclosed. Byusing a metal-containing hardmask film and by directly patterning themetal-containing film using the EUV photon flux, the process entirelyavoids the need for photoresist.

In various embodiments, a deposition (e.g., condensation) process (e.g.,ALD or MOCVD carried out in a PECVD tool, such as the Lam Vector®) canbe used to form a thin film of a metal-containing film, such aphotosensitive metal salt or metal-containing organic compound(organometallic compound), with a strong absorption in the EUV (e.g., atwavelengths on the order of 10-20 nm), for example at the wavelength ofthe EUVL light source (e.g., 13.5 nm=91.8 eV). This filmphoto-decomposes upon EUV exposure and forms a metal mask that is thepattern transfer layer during subsequent etching (e.g., in a conductoretch tool, such as the Lam 2300® Kiyo®).

The metal-containing film can be deposited in a chamber integrated witha lithography platform (e.g., a wafer stepper such as the TWINSCAN NXE:3300B® platform supplied by ASML of Veldhoven, NL) and transferred undervacuum so as not to react before exposure. Integration with thelithography tool is facilitated by the fact that EUVL also requires agreatly reduced pressure given the strong optical absorption of theincident photons by ambient gases such as H₂O, O₂, etc.

In some embodiments, a selective film deposition can be carried outafter the EUV exposure/decomposition step to increase the thickness ofthe mask material if needed for optical or mechanical reasons; a processreferred to as pattern amplification. Viewed in this context, theinitial hardmask then serves as a seed layer upon which the final maskis formed, similar to the use of a metal seed layer for electroless(ELD) or electrochemical (ECD) deposition.

Vacuum-Integrated Photoresist-less Metal Hardmask Formation Processes

FIGS. 1A-E illustrate a representative process flow for avacuum-integrated photoresist-less hardmask formation process.Generally, a metal-containing film that is sensitive to a patterningagent such as photons, electrons, protons, ions or neutral species suchthat the film can be patterned by exposure to one of these species isdeposited on a semiconductor substrate. The metal-containing film isthen patterned directly (i.e., without the use of a photoresist) byexposure to the patterning agent in a vacuum ambient to form the metalmask. This description references primarily metal-containing films,particularly where the metal is Sn, that are patterned by extremeultraviolet lithography (EUV lithography (EUVL)), particularly EUVLhaving an EUV source which uses excited Sn droplets. Such films arereferred to herein as EUV-sensitive films. However, it should beunderstood that other implementations are possible, including differentmetal-containing films and patterning agents/techniques.

A desirable hardmask metal will be a strong absorber and will have arelatively broad absorption profile, high melting point, lowmalleability/high physical stability and be readily deposited. For thepurposes of this disclosure, it is important to note that a materialthat emits a photon of a given energy will also absorb a photon of thatenergy. Strongly absorbed light will result in the desired decompositionor will otherwise sensitize the film so that the exposed areas can beremoved with heat, wet chemistry, etc. FIG. 2 provides the emissionspectrum of a EUV source which uses excited Sn droplets. See, R. W.Coons, et al., “Comparison of EUV spectral and ion emission featuresfrom laser produced Sn and Li plasmas”, Proc. Of SPIE Vol. 7636 73636-1(2010); R. C. Spitzer, et al., “Conversion efficiencies fromlaser-produced plasmas in the extreme ultraviolet region”, 79 J. Appl.Phys., 2251 (1996); and H. C. Gerritsen, et al., “Laser-generated plasmaas soft x-ray source”, J. Appl. Phys. 59 2337 (1986), incorporatedherein by reference for their disclosure relating to theemission/absorption properties of various metals. The emitted photonsare on the order of 13.5 nm or 91.8 eV. Therefore, Sn is a desirablehardmask metal for this application.

Referring to FIG. 1A, a semiconductor substrate to be patterned 100 isshown. In a typical example, the semiconductor substrate 100 is asilicon wafer including partially-formed integrated circuits.

FIG. 1B illustrates a metal-containing film 102 that is sensitive to apatterning agent deposited on the semiconductor substrate 100. Themetal-containing film may be a metal salt, for example a metal halide,or an organometallic compound sensitive to exposure to a patterningagent such that the metal-containing film gets decomposed to the basemetal or is rendered sensitive to a subsequent development process.Suitable patterning agents may be photons, electrons, protons, ions orneutral species, such that the metal-containing film 102 can bepatterned by exposure to one of these species by decomposition to thebase metal or is rendered sensitive to a subsequent development process.As further explained below, a particular example of an effective metaland patterning agent combination is Sn, deposited as a metal halide(e.g., SnBr₄) or organometallic (e.g., Sn(CH₃)₄), patterned by EUVlithography. In general, prior to the deposition, the semiconductorsubstrate 100 is placed in a reactor chamber for metal-containing filmdeposition under vacuum.

A blanket of the metal-containing film 102 can be formed by condensationfrom a suitable precursor (e.g., in a non-plasma CVD reactor, such as anAltus® CVD tool, available from Lam Research Corporation, Fremont,Calif.). For example, tin bromide, SnBr₄, has a normal boiling point of205° C. and a melting point of 31° C. at 760 Torr, and a vapor pressureof 10 Torr at 10° C. It can be condensed onto the substrate to form asolid SnBr₄ film with a thickness that depends on exposure time andsubstrate temperature, for example on the order of 5 to 200 nm, e.g., 10nm. Suitable process conditions for this deposition via condensationinclude a deposition temperature between about 0 and 30° C., for exampleabout 20° C., and a reactor pressure of less than 20 Torr, for examplemaintained between 14 and 15 Torr at 20° C. Maintaining the precursorflow rate between about 100 and 1000 sccm allows for control of thedeposition rate.

An alternative source of Sn metal may be organometallic. For example,tetramethyl tin (Sn(CH₃)₄) has a normal boiling point of 75° C. and amelting point of −54° C. at 760 Torr. It can be also be condensed ontothe substrate to form a solid Sn(CH₃)₄ film with a thickness thatdepends on exposure time and substrate temperature, for example on theorder of 5 to 200 Å, e.g., 100 Å. Suitable process conditions for thisdeposition via condensation include a deposition temperature betweenabout −54° C. and 30° C., for example about 20° C., and a reactorpressure of less than 20 Torr, for example maintained at about 1 Torr at20° C. Maintaining the precursor flow rate between about 100 and 1000sccm allows for control of the deposition rate.

Another suitable metal for formation of the metal mask is hafnium (Hf).Hafnium chloride, HfCl₄ (1 Torr vapor pressure at 190° C. with a meltingpoint of 432° C.) can be condensed onto the substrate to form a solidHfCl₄ crystalline film with a thickness that depends on exposure timeand substrate temperature, for example on the order of 50 to 2000 nm,e.g., 1000 nm. Suitable process conditions for this deposition viacondensation include a deposition temperature between about 0 and 300°C., for example about 100° C., and a reactor pressure of less than 10Torr, for example maintained between 0.1 and 1 Torr at 100° C.Maintaining the precursor flow rate between about 10 and 100 sccm allowsfor control of the deposition rate.

To prevent degradation due to water vapor, formation and transfer of theSn- and Hf-containing films is conducted in a vacuum-ambient. The formedfilm is then transferred to a EUV patterning tool and patterned viadirect exposure, without the use of a photoresist, as illustrated inFIGS. 1C-D.

It should be noted that a EUVL tool typically operates at a highervacuum than a deposition tool. If this is the case, it is desirable toincrease the vacuum environment of the substrate during the transferfrom the deposition to the patterning tool to allow the substrate anddeposited metal-containing film to degas prior to entry into thepatterning tool. This is so that the optics of the patterning tool arenot contaminated by off-gassing from the substrate.

Referring to FIG. 1C, for metal halide Sn-based metal-containing filmspatterned by EUVL, the decomposition chemistry can proceed by:

SnBr₄→Sn+2Br₂.

Photons directly decompose the SnBr₄ to Sn (tin metal) and bromine gas(Br₂). Alternatively, a reactant X₂ (e.g., wherein X is Cl, I or H)could be used to promote a reaction pathway SnBr₄+X₂→SnX₄+2B₂, andultimately to Sn by photodecomposition, in particular where SnX₄ iseasier to photo-activate than the easily condensed SnBr₄. In eithercase, the byproducts (Br₂) and reactants (X₂) require containment, suchas vacuum.

For organometallic Sn-based metal-containing films patterned by EUVL,photons directly decompose the Sn(CH₃)₄ to Sn (tin metal) and ethanegas, the decomposition chemistry proceeding by:

Sn(CH₃)₄→Sn+2C₂H₆.

For metal halide Hf-based metal-containing films patterned by EUVL, thedecomposition chemistry can proceed by:

HfCl₄→Hf+2Cl₂.

Photons directly decompose the HfCl₄ to Hf metal and chlorine gas (Cl₂).Alternatively, a reactant X₂ (e.g., wherein X is Br, I or H) could beused to promote a reaction pathway HfCl₄+X₂→HfX₄+2Cl₂, and ultimately toHf by photodecomposition, in particular where HfX₄ is easier tophoto-activate than the easily condensed HfCl₄. In either case, thebyproducts (Cl₂) and reactants (X₂) require containment, such as vacuum.

As shown in FIG. 1C, the patterning results in exposed metal-containingfilm regions of formed metal mask 102 a and unexposed regions 102 b ofmaterial to be removed by pattern development.

Referring to FIG. 1D, the pattern can then be developed. Development ofthe pattern can occur simply by heating the substrate to volatilize theunexposed regions 102 b of the metal-containing film, so that only theexposed regions 102 a remain as a fully-formed metal mask. It should benoted that this pattern development operation may not require vacuumintegration since a thermally and environmentally stable patterned metalmask would have been formed. It may also be desirable to conduct thepattern development outside the patterning tool to avoid contaminatingthe tool optics with any incompatible byproducts of the metal-containingfilm decomposition.

Referring to FIG. 1E, as an optional step, a pattern amplification canbe done. For example selective ALD or electroless deposition (ELD) maybe performed on the patterned substrate following the operationsdepicted in FIGS. 1C and/or 1D to build up the thickness of the metalmask with additional selectively deposited metal 106. This may behelpful to reduce optical transmission of the mask or make it moremechanically robust. Such amplification may be accomplished, forexample, by adaptation of an electroless deposition process such as thatdescribed in U.S. Pat. Nos. 6,911,067, 6,794,288, 6,902,605 and4,935,312, the disclosures of which in this regard are incorporated byreference herein.

For example, an initial 1 nm seed could be amplified to 10 nm in thisway. Like the pattern development discussed with reference to FIG. 1D,this operation may not require vacuum integration since a thermally andenvironmentally stable patterned metal mask would have been formedbefore amplification.

Alternative Process Embodiments

As an alternative to the metal salt or organometallic metal-containingfilm depositions, a metal-containing EUV-sensitive film could bedeposited by a multistep process of metalorganic CVD using a suitableprecursor (e.g., in a non-plasma CVD reactor, such as an Altus® CVD toolor PECVD reactor, such a Vector® PECVD tool, both available from LamResearch Corporation, Fremont, Calif.). For example, a plasma depositionof alkyl and amino precursors, such as a CH₄/H₂ plasma depositionfollowed by an ammonia (NH₃/H₂) plasma, can produce anamino-functionalized self-assembled monolayer (SAM) ofaminopropyltriethoxysilane (APTES) on a semiconductor substrate. Suchamine terminated surfaces enable conformal electroless deposition (ELD).The SAM can then be transferred to a EUV patterning tool and patterned.Selective growth of the patterned SAM by ELD, such as by PdCl₂/H₂Osolution exposure to provide a Pd catalyst, followed by ELD of Ni or Coand then copper (Cu) according to processes known in the art given theseparameters, results in a metal-based mask formed without the use ofphotoresist. Such a SAM-based approach can also be used for patternamplification as an alternative to the ELD technique described with refto FIG. 1E for that purpose.

It should also be noted that while this disclosure primarily referencesEUVL as a patterning technique, alternative embodiments could use afocused beam of electrons, ions or neutral species to directly write thepattern onto the blanket mask, these steps also performed in vacuum.In-situ chamber cleaning may be used if byproducts condense on thereflective optics of the EUVL system.

Apparatus

FIG. 3 depicts a semiconductor process cluster tool architecture withvacuum-integrated metal deposition and patterning modules that interfacewith a vacuum transfer module, suitable for implementation of thevacuum-integrated processes described herein. The arrangement oftransfer modules to “transfer” wafers among multiple storage facilitiesand processing modules may be referred to as a “cluster toolarchitecture” system. Metal deposition and patterning modules arevacuum-integrated, in accordance with the requirements of a particularprocess. A vacuum transport module (VTM) 338 interfaces with fourprocessing modules 320 a-320 d, which may be individually optimized toperform various fabrication processes. By way of example, processingmodules 320 a-320 d may be implemented to perform condensation,deposition, evaporation, ELD, etch, and/or other semiconductorprocesses. For example, module 320 a may be a non-plasma CVD reactor,such as an Altus® CVD tool, available from Lam Research Corporation,Fremont, Calif. suitable for conducting deposition of metal-containingfilms, as described herein. And module 320 b may be a PECVD tool, suchas the Lam Vector®. It should be understood that the figure is notnecessarily drawn to scale.

Airlocks 342 and 346, also known as a loadlocks or transfer modules,interface with the VTM 338 and a patterning module 340. For example, asuitable patterning module may be the TWINSCAN NXE: 3300B® platformsupplied by ASML of Veldhoven, NL). This tool architecture allows forwork pieces, such as substrates with deposited metal-containing films,to be transferred under vacuum so as not to react before exposure.Integration of the deposition modules with the lithography tool isfacilitated by the fact that EUVL also requires a greatly reducedpressure given the strong optical absorption of the incident photons byambient gases such as H₂O, O₂, etc.

Airlock 342 may be an “outgoing” loadlock, referring to the transfer ofa substrate out from the VTM 338 serving a deposition module 320 a tothe patterning module 340, and airlock 346 may be an “ingoing” loadlock,referring to the transfer of a substrate from the patterning module 340back in to the VTM 338. The ingoing loadlock 346 may also provide aninterface to the exterior of the tool for access and egress ofsubstrates. Each process module has a facet that interfaces the moduleto VTM 338. For example, deposition process module 320 a has facet 336.Inside each facet, sensors, for example, sensors 1-18 as shown, are usedto detect the passing of wafer 326 when moved between respectivestations. Patterning module 340 and airlocks 342 and 346 may besimilarly equipped with additional facets and sensors, not shown.

Main VTM robot 322 transfers wafer 326 between modules, includingairlocks 342 and 346. In one embodiment, robot 322 has one arm, and inanother embodiment, robot 322 has two arms, where each arm has an endeffector 324 to pick wafers such as wafer 326 for transport. Front-endrobot 344, it is used to transfer wafers 326 from outgoing airlock 342into the patterning module 340, from the patterning module 340 intoingoing airlock 346. Front-end robot 344 may also transport wafers 326between the ingoing loadlock and the exterior of the tool for access andegress of substrates. Because ingoing airlock module 346 has the abilityto match the environment between atmospheric and vacuum, the wafer 326is able to move between the two pressure environments without beingdamaged.

It should be noted that a EUVL tool typically operates at a highervacuum than a deposition tool. If this is the case, it is desirable toincrease the vacuum environment of the substrate during the transferfrom the deposition to the patterning tool to allow the substrate anddeposited metal-containing film to degas prior to entry into thepatterning tool. Outgoing airlock 342 may provide this function byholding the transferred wafers at a lower pressure, no higher than thepressure in the patterning module 340, for a period of time andexhausting any off-gassing, so that the optics of the patterning tool340 are not contaminated by off-gassing from the substrate. A suitablepressure for the outgoing, off-gassing airlock is no more than 1E-8Torr.

In some embodiments, a system controller 350 (which may include one ormore physical or logical controllers) controls some or all of theoperations of the cluster tool and/or its separate modules. It should benoted that the controller can be local to the cluster architecture, orcan be located external to the cluster architecture in the manufacturingfloor, or in a remote location and connected to the cluster architecturevia a network. The system controller 350 may include one or more memorydevices and one or more processors. The processor may include a centralprocessing unit (CPU) or computer, analog and/or digital input/outputconnections, stepper motor controller boards, and other like components.Instructions for implementing appropriate control operations areexecuted on the processor. These instructions may be stored on thememory devices associated with the controller or they may be providedover a network. In certain embodiments, the system controller executessystem control software.

The system control software may include instructions for controlling thetiming of application and/or magnitude of any aspect of tool or moduleoperation. System control software may be configured in any suitableway. For example, various process tool component subroutines or controlobjects may be written to control operations of the process toolcomponents necessary to carry out various process tool processes. Systemcontrol software may be coded in any suitable compute readableprogramming language. In some embodiments, system control softwareincludes input/output control (IOC) sequencing instructions forcontrolling the various parameters described above. For example, eachphase of a semiconductor fabrication process may include one or moreinstructions for execution by the system controller. The instructionsfor setting process conditions for condensation, deposition,evaporation, patterning and/or etching phase may be included in acorresponding recipe phase, for example.

Conclusion

The vacuum-integration of film deposition and lithography processes andapparatus described herein provides EUV-sensitive metal film depositionand subsequently patterning directly by direct EUV exposure in a vacuumambient to prevent their decomposition or degradation. EUVL is done in avacuum to avoid degradation of the incident 13.5 nm light flux byoptical absorption of ambient gases. Among the advantages of describedvacuum-integrated hardmask processes are: Vacuum operation of the EUVsystem opens up the possibility of using compounds that are oxygen andmoisture sensitive; vacuum integration of the deposition system with theEUV system in an apparatus enables use of these materials. Photodecomposition of a metal precursor creates a non-linear reaction wherethe photo decomposition is enhanced by the increased adsorption of themetal film. Metals are better at thermalization of high energy secondaryelectrons than photoresist, thereby improving contrast or LER. Usingmetal film directly as masks or with pattern amplification allows muchthinner films and reduce required exposure times. Metal films makebetter hardmasks for etch and decrease the thickness required from amask perspective. Moreover, further development and optimization ofmaterials compatible with the EUV vacuum and optics, organometalicprecursors with appropriate dose thresholds for metal deposition, andnucleation films with multiple photo decomposition events to eliminate anucleation site in a given space may proceed in accordance with theprocesses described herein.

It is understood that the examples and embodiments described herein arefor illustrative purposes only and that various modifications or changesin light thereof will be suggested to persons skilled in the art.Although various details have been omitted for clarity's sake, variousdesign alternatives may be implemented. Therefore, the present examplesare to be considered as illustrative and not restrictive, and theinvention is not to be limited to the details given herein, but may bemodified within the scope of the appended claims.

What is claimed is:
 1. A method of processing a substrate comprising: a)depositing an EUV-sensitive film comprising tin on a substrate; b)placing the substrate with the deposited EUV-sensitive film formed in a)in an environment of sub-atmospheric pressure to facilitate degassing ofthe deposited EUV-sensitive film; c) exposing of a portion of thedeposited EUV-sensitive film to EUV radiation to form a pattern ofexposed and unexposed regions in the deposited EUV-sensitive film,wherein the EUV radiation has a wavelength in a range of 10 to 20 nm;and d) performing a pattern development process to remove portions ofthe deposited EUV-sensitive film.
 2. The method of claim 1, wherein thepattern development process comprises heating the substrate with thedeposited EUV-sensitive film.
 3. The method of claim 1, wherein b) isperformed at a pressure of no more than 1E⁻⁸ Torr.
 4. The method ofclaim 1, wherein c) is performed in a vacuum integrated system.
 5. Themethod of claim 1, wherein a) and b) are performed in a vacuumintegrated system.
 6. The method of claim 1, wherein a) and b) areperformed in separate modules connected by a common vacuum transfermodule.
 7. The method of claim 1, wherein b) and c) are performed in avacuum integrated system.
 8. The method of claim 1, wherein b) and c)are performed in separate modules connected by a common vacuum transfermodule.
 9. The method of claim 1, wherein c) and d) are performed in avacuum integrated system.
 10. The method of claim 1, wherein c) and d)are performed in are performed in separate modules connected by a commonvacuum transfer module.
 11. A system for processing a semiconductorsubstrate comprising: a plurality of process modules, the processmodules including a) a deposition module for depositing an EUV-sensitivemetal-containing film comprising tin on a semiconductor substrate; b) adegassing module for degassing the EUV-sensitive metal-containing filmunder sub-atmospheric pressure; c) an exposure module for exposing aportion of the EUV-sensitive metal-containing film to EUV radiation witha wavelength in a range of 10 to 20 nm in an EUV-patterning tool to forma patterned film comprising exposed and unexposed regions; and d) adevelopment module for performing a pattern development process toremove unexposed regions of the patterned film.
 12. The system of claim11, wherein the pattern development process includes heating thesemiconductor substrate with the patterned film.
 13. The system of claim11, wherein b) is at a pressure of no more than 1E⁻⁸ Torr.
 14. Thesystem of claim 11, further comprising a common transfer moduleconnecting at least two of the process modules in the system.
 15. Thesystem of claim 11, wherein the semiconductor substrate is transferredbetween process modules under vacuum.
 16. The system of claim 11,wherein the semiconductor substrate is transferred between processmodules in a controlled environment.
 17. A method of processing asubstrate comprising: depositing an EUV-sensitive film comprising tin ona substrate in a process chamber; and exposing of a portion of theEUV-sensitive film to EUV radiation in a photolithography chamber havingan EUV source to form a pattern of exposed and unexposed regions in theEUV-sensitive film; wherein the EUV source emits a radiation having awavelength in a range of about 10 nm to 20 nm; and wherein the processchamber is integrated onto a lithography platform.
 18. The method ofclaim 17, wherein the lithography platform is a wafer stepper.
 19. Themethod of claim 17, wherein the EUV-sensitive film deposited on thesubstrate is transferred between the process chamber and the lithographychamber in a controlled environment.
 20. A system for processing asubstrate comprising: a deposition chamber for depositing anEUV-sensitive film comprising tin on a substrate; and an exposure modulefor exposing of a portion of the EUV-sensitive film to EUV radiation ina photolithography chamber having an EUV source to form a pattern ofexposed and unexposed regions in the EUV-sensitive film, wherein the EUVsource emits a radiation having a wavelength in a range of about 10 nmto 20 nm; and wherein the deposition chamber is integrated onto alithography platform.
 21. The system of claim 20, wherein thelithography platform is a wafer stepper.
 22. The system of claim 20,wherein the EUV-sensitive film deposited on the substrate is transferredbetween the deposition chamber and the lithography chamber in acontrolled environment.